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本文报道全氟(4-甲基-3,6-二氧杂-7-辛烯)磺酰氟(1)、全氟(3-氧杂-4-氟羰基戊)磺酰氟(2)和全氟(4,6-二甲基-3-氧杂庚-5-酮)磺酰氟(3)的光化学反应. 相似文献
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由全氟酰氟和氟砜基二氟乙酰氟分别合成了全氟烷基羧酸全氟苯酯(1)和全氟苯氧羰基二氟甲烷磷酸全氟苯酯(2)。研究了1和2的亲核取代反应,发现1比全氟磺酸全氟苯酯更易与亲核试剂作用,试剂均进攻于羧基碳上。在2的亲核反应中,其羧基碳亦比磺基硫原子更易受试剂的进攻。 相似文献
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将全氟联苯、 二(4-氟苯基)苯基氧膦与4-(4′-羟基)苯基-2,3-二氮杂萘酮共聚, 合成了含全氟联苯结构的聚二氮杂萘酮醚氧膦, 再经磺化反应, 制备了含全氟联苯结构的磺化聚二氮杂萘酮醚氧膦(sPEPOF-x, x为含氟重复单元的摩尔分数)质子交换膜. 由于强疏水全氟联苯结构促进了聚合物膜的亲水/疏水微相分离, 提高了质子电导率, 降低了溶胀率, sPEPOF质子交换膜表现出优良的综合性能. 在80 ℃下, sPEPOF-25质子交换膜的溶胀率仅为10%, 约为Nafion 117的一半, 而其电导率为0.099 S/cm, 约为Nafion 117的1.2倍, 且耐氧化稳定性好, 热稳定性高, 具有潜在的应用前景. 相似文献
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EPR研究表明,全氟酰基过氧化物在室温下可将脂肪族仲胺氧化成相应的稳定双烷基氮氧自由基。它们与RNH2的氧化反应是单电子转移过程,生成烷基-全氟酰氧基氮氧自由基RN(O·)OCORF;当R为叔烷基时,还生成RN(O·)R、RN(O·)H、RN(O·)RF和RN(O·)RF′(RF′=RF-CF2)等4种稳定性差别很大的氮氧自由基。EPR研究结果揭示了该反应机理的重要信息。 相似文献
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以Ce^4^+-NaHSO3存在的体系中, 全氟烷基碘与烯烃于50-70℃发生加成反应, 得到相应的加成物, 在Fe^3^+-NaHSO3引发下, 或全氟烷基亚磺酸钠存在下也能引发同样的加成反应. 在全氟烷基亚碘酸钠存在下, 于30℃的反应中没有发现全氟烷基亚碘酸钠的全氟烷基与烯烃的加成物形成. 相似文献
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5-卤-3-氧杂-全氟戊磺酰氟(1)依次用苛性钾、浓硫酸和五氧化二磷处理可顺利地得到相应的磺酸和磺酸酐.在吡啶存在下,[I(CF_2)_2O(CF_2)_2SO_2]_2O(3)与醇反应得磺酸酯(6).1在发烟硫酸作用下,可转化成酰氟9.随着反应温度的不同,9水解为酸10和/或二元酸11.氟羰基全氟甲磺酰氟的水解也有类似现象.醇与9的酰氟基反应得羧酸酯,而不与磺酰氟基反应.但可进一步转化为磺酸酯.由9与F~-生成的全氟烷氧基阴离子-O(CF_2)_2O(CF_2)_2SO_2F与活泼的卤代烷作用得醚.还研究了5-卤-3-氧杂-全氟戊磺酰氟与三氯化铝的作用,在无水三氯化铝存在下对9进行了芳烃的Friedel-Crafts酰基化,以四氯化碳为溶剂并改变加料顺序,可提高酮的产率. 相似文献
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全氟丙酮是合成有机氟化物的重要原料之一。其合成方法文献已有报导。我们研究了1,2-全氟环氧丙烷在三氯化铝存在下的催化重排反应,为全氟丙酮的制备提供了更简便的方法。一、实验部分原料:无水AlCl_3(C.P级)。每次新装入反应器的三氯化铝都要在70℃下通氮活化。 1,2-全氟环氧丙烷,在使用之前先通过5%的NaOH水溶液洗瓶,P_2O_5干燥塔,KOH干燥塔及硷石灰干燥塔,以除去水及酸性物质。反应器:玻璃管,表面涂有电热涂料(供加热之用);反应区内径为1.8厘米,长55厘米, 相似文献
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1,2-二环戊二烯基四甲基二硅烷与正丁基锂作用生成(四甲基二硅撑)双[环戊二烯基负离子盐],后者随即与六羰基钼反应即形成1,1'-(四 甲基二硅撑)双[环戊二烯基三羰基钼负离子盐],分别与四种不同的卤化物反应,生成在钼原子上发生烃基化的产物与冰醋酸作用,随即分别与CCl~4及NBS反应,生成相应的钼氯化物和钼溴化物作用发生氧化偶联反应,生成Mo-Mo键断裂的钼碘化物,以元素分析、IR及^1HNMR表征了2-9的结构.并对5的单晶进行了X射线衍射分析.它的晶体属三斜晶系,PI空间群,晶体学数据:偏差因子R=0.043,R~W=0.055. 相似文献
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Reactions of monooxidized thioyl and selenoyl bis(phosphanyl)amine ligands C10H7‐1‐N(P(E)Ph2)(PPh2) [E = S ( 1 ), Se ( 2 )] with Mo(CO)4(pip)2 and W(CO)4(cod) afforded the complexes [M(CO)4{ 1 ‐κ2P,S}] [M = Mo ( 3 ), W ( 4 )] and [M(CO)4{ 2 ‐κ2P,Se}] [M = Mo ( 5 ), W ( 6 )]. Complexes 3 – 6 were characterized by multinuclear NMR (1H, 13C, 31P, and 77Se NMR) and IR spectroscopy. Crystal‐structure determinations were carried out on 3 , 5 , and 6 , which represent the first examples of structurally characterized complexes of such ligands with group‐6 metal carbonyls. 相似文献
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本文根据分子碎片结合原理, 用直接法由简单的单质元素, 金属盐类及配体, 通过控制反应温度、压力, 时间及配体用量在CO气氛下一步合成含羰基和不含羰基的簇合物: Pd3(SC6H4OH)3(PPh3)3(OH)2Cl(1),Fe2S2(CO)5Pd(PPh3)3(2), Fe2S2(CO)5Pt(PPh3)3(3)。对它们进行了IR, NMR,EDS, 元素分析, 金属分析和化合物1的X光单晶衍射结构分析。化合物1属单斜晶系, 离子型, P21/n空间群, 晶胞参数a=1.4629(3)nm, b=1.9263(3)nm,c=2.4908(7)nm, β=94.53(2)°, Z=4, R=0.053。 相似文献
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二硝酸(N,N,N',N'-四正丁基丁二酰胺)合铀(Ⅱ)酰配合物的合成和结构 总被引:4,自引:0,他引:4
合成的配合UO~2[Bu~2NCO(CH~2)~2CONBu~2](NO~3)~2的晶体属四方晶系,a=b=3.3207(8),c=1.0711(4)nm,α=β=γ=90.00(0)°,V=11.811(7)nm^3,D~c=1.65g.cm^-3,Z=16,空间群为14~1/\α.配合物分子中铀酰离子由六个氧原子配位,其中四个来自两个硝酸根,另外两个来自有机配体的两个羰基,两个硝酸根被七原子环排斥而挤在一边,以铀原子为中心的六方双锥结构受到扭曲. 相似文献
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四羰基二(五甲二硅基环戊二烯基)二钼的合成及反应 总被引:3,自引:0,他引:3
本文进一步报道四羰基二(五甲二硅基环戊二烯基)二铜的合成及反应, 五甲二硅基环戊二烯与六羰基钼在甲苯中加热回流9h, 即生成含Mo-Mo键的双核钼配合物1, 1在甲苯中进一步加热回流, 则发生脱羰而生成标题化合物。 相似文献
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In order to study the Fe-Cu interactions and their effects on 31p NMR, the structures of mononuclear complex Fe(CO)3fPhzPpy)a 1 and binuclear complexes Fe(CO)3(PhEPpy)z(CuXn) (2: Xn = Cl2^2-, 3: Xn = Cl-, 4: Xn = Br-) are calculated by density functional theory (DFT) PBE0 method. For complexes 1, 3 and 4, the 31p NMR chemical shifts calculated by PBE0-GIAO method are in good agreement with experimental results. The 31p chemical shift is 82.10 ppm in the designed complex 2. The Fe-Cu interactions (including Fe→Cu and Fe←Cu charge transfer) mainly exhibit the indirect interactions. Moreover, the Fe-Cu(I) interactions (mostly acting as σFe-p→4Scu and aFe-C→4Scu charge transfer) in complexes 3 and 4 are stronger than Fe-Cu(Ⅱ) interactions (mostly acting as σFe-p→4Scu and σFe-p←4Sc,) in complex 2. In complex 2, the stronger Fe←Cu interac- tions, acting as σFe-p←44SCu charge transfer, increase the electron density on P nucleus, which causes the upfield 31p chemical shift compared with mononuclear complex 1. For 3 and 4, although a little deshielding for P nucleus is derived from the delocalization of σFe-p→4Scu due to the Fe→Cu interactions, the stronger σFe-c→np charge-transfer finally increases the electron density on P nucleus. As a result, an upfield 31p chemical shift is observed compared with 1. The stability follows the order of 2〉3=4, indicating that Fe(CO)3(PhzPpy)2(CuCl2) is stable and could be synthesized experimentally. The N-Cu(Ⅱ) interaction plays an important role in the stability of 2. Because the delocalization of σFe-p→4SCu and σFe-c→πc-o weakens the a bonds of Fe-C and ~r bonds of CO, it is favorable for increasing the catalytic activity of binuclear complexes. Complexes 3 and 4 are expected to show higher catalytic activity compared to 2. 相似文献
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Transition Metal Complexes of P-rich Phosphanes and Silylphosphanes. VII Carbonyl Complexes of the Heptaphosphane(3) iPr2(Me3Si)P7 From the reaction of iPr2(Me3Si)P7 1 with one equivalent of Cr(CO)5THF the yellow products iPr2(H)P7[Cr(CO)5] 2 and iPr2(Me3Si)P7[Cr(CO)5] 3 were isolated by column chromatography on silicagel. The P? H group in 2 results from a cleavage of the P? SiMe3 bond during chromatography. The Cr(CO)5 group in 2 is linked to an iPr? Pe atom, in 3 to the Me3Si? Pe atom of the P7 skeleton. The substituents do not force the formation of a single isomer; nevertheless 3 ist considerably favoured as compared to 2 . From the reaction of 1 with 2 equivalents of Cr(CO)5THF the yellow iPr2(H)P7[Cr(CO)5]2 4 was isolated bearing one Cr(CO)5 group at an iPr? Pe atom, the other one at a Pb atom of the P7 skeleton. Compound 3 yields with Cr(CO)4NBD the red iPr2(Me3Si)P7[Cr(CO)5][Cr(CO)4] 5 . Three isomers of 5 appear. Two Pe atoms of 5 are bridged by the Cr(CO)4 group, the third Pe atom is linked to the Cr(CO)5 ligand. iPr2(H)P7[Fe(CO)4] was isolated from the reaction of 1 with Fe2(CO)9. 31P NMR and MS data are reported. 相似文献
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Theoretical Studies on the Fe-M Interactions and 31P NMR in Fe(CO)3(EtPhPpy)2MX2 (X=NCS,SCN, Cl; M=Zn,Cd, Hg) 
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下载免费PDF全文 To study the Fe?M interactions and their effects on 31P NMR, the structures of Fe(CO)3(EtPhPpy)2 1,Fe(CO)3(EtPhPpy)2M(NCS)2 (2: M=Zn, 3: M=Cd, 4: M=Hg) and Fe(CO)3(EtPhPpy)2CdX2 (5: X=Cl,6: X=SCN) were investigated by density functional theory (DFT) PBE0 method. The stabilities S of complexes follow S(2)>S(3)>S(4) and S(3)≈S(6)>S(5), indicating that 6 is stable and may be synthesized.The complexes with thiocyanate are more stable than that with chloride in Fe(CO)3(EtPhPpy)2CdX2.The strength I of Fe-M interactions follows I(2)≈I(3)相似文献